Magnetic Material Cutting Performance Characteristics:
Due to the use of metal materials as the core, the rigidity of the cutting blade has been improved, making it more suitable for deep cuts.
The working layer's wear resistance ensures a long service life for the blade.
A variety of bonding types are offered, catering to the selection of more suitable cutting blades for different processing objects.
Accurate control of diamond grit size and concentration ensures that the blade maintains excellent sharpness during cutting, resulting in smooth, high-gloss cutting surfaces with good perpendicularity.
Our precision manufacturing processes ensure high accuracy in the geometric dimensions of the blades.
Scope of Application:
This series of products is suitable for precision machining of difficult-to-process materials, including optical glass, crystalline materials, magnetic materials, semiconductor materials, and fine ceramic materials, as well as brittle metal materials.
Magnetic materials, commonly referred to as magnetic materials, are strong magnetic substances that have been a time-honored and widely-used functional material. The magnetic properties of matter were recognized and applied as early as 3,000 years ago, such as ancient compasses using magnets. Modern magnetic materials are extensively used in our daily lives, including permanent magnets in motors, iron cores in transformers, magnetic optical disks for storage, and magnetic diskettes for computers. Magnetic materials are closely related to information technology, automation, mechatronics, national defense, and various aspects of the national economy. It is generally believed that magnetic materials refer to substances that can produce magnetism directly or indirectly, such as transition elements like iron, cobalt, nickel, and their alloys. Magnetic materials can be divided into soft magnetic materials and hard magnetic materials based on the ease of demagnetization after magnetization. Materials that are easily demagnetized are called soft magnetic materials, while those that are not easily demagnetized are called hard magnetic materials. Generally, soft magnetic materials have smaller residual magnetism, while hard magnetic materials have larger residual magnetism.
The working principle of a slicer is relatively simple—it utilizes the sharp cutting surface of the slicer to cut objects and materials into slices according to a specified ratio or width, suitable for production or manufacturing purposes. Commonly, the worktable of an internal circular slicer is of a fixed height, and materials of different heights require manual adjustment. This manual adjustment is not only time-consuming and labor-intensive but also hampers efficiency, making it extremely inconvenient during actual production and manufacturing processes.
